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随机大气条件下太阳能光伏系统可调步长最大功率点跟踪控制器的设计与综合分析

Design and comprehensive analysis of adjustable step MPPT controllers for solar PV systems under stochastic atmospheric conditions.

作者信息

Ashwini M, Basha C H Hussaian, Alraddadi M, Alsaif Faisal, Irfan Mohammed Mujahid

机构信息

The Centre for Emerging Energy Technologies (CEET), Department of Electrical & Electronics Engineering, SR University, Warangal, 506371, Telangana, India.

Electrical Engineering Department, Yanbu industrial college, Saudi Arabia, Saudi Arabia.

出版信息

Sci Rep. 2025 Mar 26;15(1):10369. doi: 10.1038/s41598-025-95136-1.

DOI:10.1038/s41598-025-95136-1
PMID:40133386
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11937563/
Abstract

At present, power transmission systems are moving to renewable sources because their features are more reliable, easy to install, increase public health, and lower development costs when associated with conventional energy systems. Here, solar technology is considered because of its advantages when equated with other renewable sources are free energy production, good energy density, low air pollutants, and less maintenance requirement. In this article, a triple diode cell technology is considered for achieving the accurate voltage of the PV, and its power production is increased by proposing the Adjustable Cuckoo Search Methodology (ACSM). Here, the ACSM is studied by comparing it with the other swarm and conventional Maximum Power Point Tracking (MPPT) methodologies. The proposed MPPT controller tracks the MPP with 0.025 s time duration at 355 K. Finally, the one-switch non-isolated voltage improvement DC-DC circuit is used in the proposed system for giving the wide voltage gain to the consumer loads. The proposed ACSM-fed DC-DC converter system is investigated by utilizing the MATLAB/Simulink tool and the converter is investigated experimentally by applying the programmable power source.

摘要

目前,输电系统正朝着可再生能源方向发展,因为与传统能源系统相比,可再生能源系统更可靠、易于安装、有利于公众健康且开发成本更低。在此,考虑太阳能技术是因为与其他可再生能源相比,它具有以下优势:免费生产能源、良好的能量密度、低空气污染物以及维护需求较少。在本文中,为实现光伏电池的精确电压,考虑采用三二极管电池技术,并通过提出可调布谷鸟搜索方法(ACSM)来提高其发电量。在此,通过将ACSM与其他群体智能和传统最大功率点跟踪(MPPT)方法进行比较来研究ACSM。所提出的MPPT控制器在355 K温度下以0.025 s的时间持续跟踪最大功率点。最后,在所提出的系统中使用单开关非隔离式电压提升DC - DC电路,为用户负载提供宽电压增益。通过使用MATLAB/Simulink工具对所提出的由ACSM供电的DC - DC变换器系统进行研究,并通过应用可编程电源对变换器进行实验研究。

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本文引用的文献

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Development of a fixed-order [Formula: see text] controller for a robust P&O-MPPT strategy to control poly-crystalline solar PV energy systems.用于控制多晶硅太阳能光伏能源系统的稳健P&O-MPPT策略的固定阶[公式:见文本]控制器的开发。
Sci Rep. 2025 Jan 23;15(1):2923. doi: 10.1038/s41598-025-86477-y.
2
Interleaved quartic high gain DC-DC converter.交错式四次高增益直流-直流转换器。
Sci Rep. 2025 Jan 2;15(1):216. doi: 10.1038/s41598-024-84015-w.